characteristics of the windings. Th

characteristics of the windings. The transient
waves propagate into the winding with a certain
velocity, the winding has a certain wave transit
time, and the wavefront of the transient can be
regarded as being distributed along a length of
the winding. For a steep-fronted voltage surge,
most of the wave front will reside across the first
few turns, which can be overstressed. The wave
front slopes off and the amplitude is attenuated as
the wave penetrates along the winding, because
of damping due to the eddy currents. For all
practical winding structures, this phenomenon is
quite complex and can only be investigated by
constructing a detailed model and carrying out a
numerical solution for the transient response and
frequency characteristics in the regions of concern.
Two types of models can be then considered
for analyzing the response of power apparatus
windings under high frequency stresses:
• Internal models, which are aimed at analyzing
the voltage distribution within the
winding. Voltage stresses in the winding
under the conditions imposed by a
steep-fronted input surge depend on location
and time. An accurate model may
consider each turn of the winding represented
by capacitances, inductances and
losses (Greenwood, 1991; Chowdhuri,
2004; Bewley, 1951; Heller & Veverka,
1968, Rudenberg, 1968; Degeneff, 2007).
Winding capacitances play a vital role in
establishing the initial voltage distribution
along the winding when a steep-fronted
voltage is suddenly applied. Under these
conditions, displacement currents can flow
in the winding capacitance, but they cannot
flow in the winding itself because of its
inductance. As for other transient studies,
an equivalent circuit representation can be
used for finding the internal response of a
winding to surge voltages.
• Terminal models, which can be used to
analyze the interaction of the component